Robust nano-architectured composite thin films for a low-temperature solid oxide fuel cell cathode

Abstract

Thin-film based, low-temperature solid oxide fuel cells (LT-SOFCs), manufactured using micro-fabrication techniques, have gained much attention due to their capability to reduce the operating temperature (< $450 ^\circ C$) and the ensuing extended life and reduced cost, compared to conventional SOFCs. While highly porous and continuously connected Pt thin films are viewed as an attractive cathode, they are readily apt to sinter and grow into larger, isolated crystallites upon annealing, leading to severe degradation of the cathode performance over time. Here, we address this issue by fabricating a post-encapsulated composite structure, in which gas-permeable and catalytically active solid electrolytes surround porous Pt electrodes. Nanoporous Pt thin films deposited onto a yttria-stabilized $ZrO_2$ (YSZ) single-crystal substrate are uniformly coated with Sm-doped $CeO_2$ (SDC) via a simple, cost-effective and scalable coating method known as cathodic electrochemical deposition (CELD). Physical characterization of the nanostructured Pt/SDC composite thin films is done using a range of tools, in this case SEM, TEM, XRD and ICP-MS. AC impedance spectroscopy (ACIS) of symmetric cells (cathode

electrolyte

cathode) with SDC coatings reveals that the enhanced Pt-SDC interactions led to exceptionally high ORR activity and outstanding thermal stability. These observations provide new directions for the achievement of a robust and catalytically active LT-SOFC cathode through modification of the metal surface.